Inspiratory synthesis of nitric oxide

ABSTRACT

A system for generating nitric oxide can include an apparatus positioned in a trachea of a mammal, the apparatus in eluding a respiration sensor for collecting information related to one or more triggering events associated with the trachea, an oxygen sensor for collecting information related to a concentration of oxygen in a gas, and one or more pairs of electrodes for initiating a series of electric arcs to generate nitric oxide, and the system for generating nitric oxide can also include a controller for determining one or more control parameters based on the information collected by the respiration sensor and the oxygen sensor, wherein the series of electric arcs is initiated based on the control parameters determined by the controller.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 14/777,072 filed Sep. 15, 2015, which represents the national stage entry of PCT International Application No. PCT/US2014/028439 filed Mar. 14, 2014, which claims priority to U.S. Patent Application Ser. No. 61/789,161 filed Mar. 15, 2013, and U.S. Provisional Application Ser. No. 61/792,473, filed Mar. 15, 2013, which are hereby incorporated by reference in their entirety for all purposes.

TECHNICAL FIELD

This invention related to synthesis of nitric oxide triggered by inspiratory flow.

BACKGROUND

Nitric oxide (NO) is crucial to many biological systems, and is known to mediate the control of blood pressure, help the immune system kill invading parasites that enter cells, inhibit division of cancer cells, transmit signals between brain cells, and contribute to the large scale death of brain cells that can debilitate people with strokes or Huntington's disease. Nitric oxide also mediates relaxation of smooth muscle present, for example, in the walls of the blood vessels, bronchi, gastrointestinal tract, and urogenital tract. Administration of nitric oxide gas to the lung by inhalation has been shown to produce localized smooth muscle relaxation to treat bronchial constriction and pulmonary hypertension, pneumonia, etc. in adults and children without systemic side effects.

Inhaled nitric oxide is a potent local pulmonary vasodilator and bronchodilator that improves the matching of ventilation with perfusion, thereby increasing the injured lungs oxygen transport efficiency and raising the arterial oxygen tension. Nitric oxide combines a rapid onset of action occurring within seconds with the absence of systemic vasodilatory effects. Once inhaled, it diffuses through the pulmonary vasculature into the bloodstream, where it is rapidly inactivated by combination with hemoglobin. Therefore, the bronchodilator effects of inhaled nitric oxide are limited to the airway and the vasodilatory effects of inhaled nitric oxide are limited to the pulmonary vasculature. The ability of nitric oxide to dilate pulmonary vessels selectively provides therapeutic advantages in the treatment of acute and chronic pulmonary hypertension.

U.S. Pat. No. 5,396,882 to Zapol, which is incorporated by reference herein, describes electric generation of nitric oxide (NO) from air at ambient pressure for medical purposes. As described in U.S. Pat. No. 5,396,882, an air input port of the system is used for continuously introducing air into the electric arc chamber. Unwanted by-products formed during the production of NO (e.g., nitrogen dioxide (NO₂) and ozone (O₃)) are absorbed, for example, by a scavenger or catalytic converter before the electrically generated NO is used for medical purposes.

NO oxidizes in an oxygen-containing atmosphere to form NO₂. NO₂ is a toxic by-product which forms nitric acid when dissolved in airway secretions or cells. Generating NO with low levels of NO₂ is often desirable.

SUMMARY

In some aspects, a method includes collecting information related to one or more triggering events associated with a respiratory system. The method also includes determining one or more control parameters based on the collected information. The method also includes initiating a series of electric arcs to generate nitric oxide based on the determined control parameters.

Embodiments can include one or more of the following.

The triggering event can be a reduction of temperature due to an inspiration of gas.

The triggering event can be a flow of gas.

The information related to one or more triggering events can include one or more of an onset time of an inspiration, a tidal volume of an inspiration, a temperature of an inspired gas, and a concentration of oxygen in a reactant gas.

The series of electric arcs can be produced when the triggering event occurs.

The series of electric arcs can be produced a pre-defined amount of time before the triggering event occurs.

A pulse train can initiate the series of electric arcs, and the pulse train can include pulse groups having pulses with different pulse widths.

The pulse width of initial pulses in one of the pulse groups can be wider than other pulses in the pulse group.

The series of electric arcs can generate a reduced level of nitrogen dioxide or ozone.

The reduced level of nitrogen dioxide can have a concentration that is less than 20%, 10%, 6%, or 5% of a concentration of the generated nitric oxide.

The respiratory system can include a trachea.

The respiratory system can include one or both of a tracheostomy tube and an endotracheal tube.

The respiratory system can include a patient wearable mask.

In some additional aspects, an apparatus includes a respiration sensor for collecting information related to one or more triggering events associated with a respiratory system. The apparatus also includes an oxygen sensor for collecting information related to a concentration of oxygen in a gas. The apparatus also includes a controller for determining one or more control parameters based on the collected information. The apparatus also includes electrodes for initiating a series of electric arcs to generate nitric oxide based on the determined control parameters.

Embodiments can include one or more of the following.

The triggering event can be a reduction of temperature due to an inspiration of gas.

The triggering event can be a flow of gas past the respiration sensor.

The information related to one or more triggering events can include one or more of an onset time of an inspiration, a tidal volume of an inspiration, a temperature of an inspired gas, and a concentration of oxygen in a reactant gas.

The electrodes can produce the series of electric arcs when the triggering event occurs.

The electrodes can produce the series of electric arcs a pre-defined amount of time before the triggering event occurs.

A pulse train can initiate the series of electric arcs, and the pulse train can include pulse groups having pulses with different pulse widths.

The pulse width of initial pulses in one of the pulse groups can be wider than other pulses in the pulse group.

The series of electric arcs can generate a reduced level of nitrogen dioxide or ozone.

The reduced level of nitrogen dioxide can have a concentration that is less than 20%, 10%, 6%, or 5% of a concentration of the generated nitric oxide.

The respiratory system can include a trachea.

The respiratory system can include one or both of a tracheostomy tube and an endotracheal tube.

The respiratory system can include a patient wearable mask.

The patient wearable mask can include one or more valves for separating an inspiratory gas flow from an expiratory gas flow.

The sensor or the electrodes can be configured to be positioned in a trachea.

The electrodes can include a noble metal.

The electrodes can include iridium.

The electrodes can include nickel.

In some additional aspects, a system for generating nitric oxide includes an apparatus positioned in a trachea of a mammal. The apparatus includes a respiration sensor for collecting information related to one or more triggering events associated with the trachea. The apparatus also includes an oxygen sensor for collecting information related to a concentration of oxygen in a gas. One or more pairs of electrodes are included in the apparatus for initiating a series of electric arcs to generate nitric oxide. The system for generating nitric oxide also includes a controller for determining one or more control parameters based on the information collected by the respiration sensor and the oxygen sensor, wherein the series of electric arcs is initiated based on the control parameters determined by the controller.

Embodiments can include one or more of the following.

The triggering event can be a reduction of temperature due to an inspiration of gas.

The triggering event can be a flow of gas past the respiration sensor.

The information related to one or more triggering events can include one or more of an onset time of an inspiration, a tidal volume of an inspiration, a temperature of an inspired gas, and a concentration of oxygen in a reactant gas.

The electrodes can produce the series of electric arcs when the triggering event occurs.

The electrodes can produce the series of electric arcs a pre-defined amount of time before the triggering event occurs.

A pulse train can initiate the series of electric arcs, and the pulse train can include pulse groups having pulses with different pulse widths.

The pulse width of initial pulses in one of the pulse groups can be wider than other pulses in the pulse group.

The series of electric arcs can generate a reduced level of nitrogen dioxide or ozone.

The reduced level of nitrogen dioxide can have a concentration that is less than 20%, 10%, 6%, or 5% of a concentration of the generated nitric oxide.

The electrodes can include a noble metal.

The electrodes can include iridium.

The electrodes can include nickel.

In some additional aspects, an apparatus implantable in the intercartilaginous rings in the neck includes a respiration sensor for collecting information related to one or more triggering events associated with a respiratory system. The apparatus also includes an oxygen sensor for collecting information related to a concentration of oxygen in a gas. The apparatus also includes a controller for determining one or more control parameters based on the collected information. One or more pairs of electrodes are included in the apparatus and reside inside a spark chamber, the electrodes for initiating a series of electric arcs to generate nitric oxide based on the determined control parameters, wherein the spark chamber is separated from an external environment by a membrane that is permeable to nitric oxide and impermeable to nitrogen dioxide and ozone.

Embodiments can include one or more of the following.

The apparatus can also include a sweeping device for removing mucus from the membrane.

In some additional aspects, an apparatus implantable in the trachea of a mammal using the Seldinger technique includes a respiration sensor for collecting information related to one or more triggering events associated with a respiratory system. The apparatus also includes an oxygen sensor for collecting information related to a concentration of oxygen in a gas. The apparatus also includes a controller for determining one or more control parameters based on the collected information. One or more pairs of electrodes are included in the apparatus for initiating a series of electric arcs to generate nitric oxide based on the determined control parameters.

The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram of a system for producing NO.

FIG. 2A shows an example of an NO generator.

FIG. 2B shows an example of an NO generator.

FIG. 2C shows an example of an NO generator.

FIG. 2D shows an example of an NO generator.

FIG. 3 depicts a representation of a pulse train and a pulse group.

FIG. 4 is a circuit diagram of an example of a portion of a respiration sensor.

FIG. 5 depicts an example of a voltage time series from a respiration sensor.

FIG. 6A shows average current and voltage as a function of sparks per second.

FIG. 6B shows average power as a function of sparks per second.

FIGS. 7A-B show tracings of voltage and current during two sparks of a 1 spark/second discharge.

FIG. 8 shows NO and NO₂ concentrations using various electrode materials.

FIG. 9 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations.

FIG. 10 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations.

FIG. 11 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations.

FIG. 12 shows ozone levels at various oxygen concentrations.

FIG. 13 shows ozone levels at various oxygen concentrations.

FIG. 14 shows ozone levels at various oxygen concentrations.

FIG. 15 shows ozone levels at various oxygen concentrations.

FIG. 16 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations.

FIG. 17 shows mean pulmonary artery pressure over an infusion period.

FIG. 18 shows NO and NO₂ concentrations at various FiO₂.

FIG. 19 shows mean pulmonary artery pressure at various FiO₂.

FIG. 20 shows NO and NO₂ concentrations at various FiO₂.

FIG. 21 shows mean pulmonary artery pressure at various FiO₂.

FIG. 22 shows mean pulmonary artery pressure at various tidal volumes.

FIG. 23 shows NO and NO₂ concentrations at various tidal volumes.

FIG. 24 shows a test setup for measuring NO and NO₂ levels in a hypobaric chamber at various atmospheric pressures.

FIG. 25 shows NO and NO₂ levels at various atmospheric pressures.

FIG. 26 shows mean pulmonary artery pressure over an infusion period.

FIG. 27 shows mean pulmonary artery pressure while breathing NO.

FIG. 28 shows mean pulmonary artery pressure during sparking triggered upon inspiration.

FIG. 29 shows mean pulmonary artery pressure during continuous sparking.

FIG. 30 shows a spark plug installed in a sheep's airway.

FIG. 31 shows mean pulmonary artery pressure during an infusion period of the pulmonary vasoconstrictor U46619.

FIG. 32 shows mean pulmonary artery pressure while breathing NO.

FIG. 33 shows mean pulmonary artery pressure during sparking triggered upon inspiration.

FIG. 34 shows a bench test setup with a sheep airway simulator.

FIG. 35 shows NO production under a constant reactant gas flow rate using a modified mini spark plug with a circuit gap.

FIG. 36 shows a modified mini spark plug with a circuit gap.

FIG. 37 is a flowchart.

FIG. 38 illustrates an example of a computing device and a mobile computing device that can be used to implement the operations and techniques described herein.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

As described herein, electrical synthesis of nitric oxide is initiated upon (or before) inspiration to provide in-situ, on-demand production of nitric oxide for therapeutic use. FIG. 1 shows an example of a system 100 for producing NO in a respiratory system. In some examples, a respiratory system includes the trachea of a mammal, a respiratory mask, nasal prongs, a ventilator, or an anesthesia machine, to name a few. A reactant gas (e.g., air, or a 20-90% oxygen mixture in nitrogen) enters an NO generator 102, and a product gas (including NO) exits the NO generator 102. The NO generator 102 includes electrodes 106, a respiration sensor 108, and a controller 110. If the reactant gas is a gas other than air, the NO generator 102 can include an oxygen sensor 112. The oxygen sensor 112 can be an electrode configured to detect the concentration of oxygen in the reactant gas. The electrodes 106 generate sparks in the presence of the reactant gas to produce NO 104, as described herein.

In some embodiments, the NO generator 102 is portable and wearable. For example, FIG. 2A shows an example of an NO generator 200 for producing NO that can reside within the trachea of a mammal. The device can be placed in the larynx with a fiber bronchoscope, and anchored to the tracheal wall. FIG. 2A depicts a cross-sectional view of a trachea 202 with tracheostomy or endotracheal tube 204 positioned in the trachea 202. The NO generator 200 is coupled to the tracheostomy or endotracheal tube 204. The NO generator 200 includes electrodes 206 and respiration sensor 208. In some examples, the NO generator 200 includes an oxygen sensor 209. The NO generator 200 may include a controller 210 that is coupled to the electrodes 206, the respiration sensor 208, and the oxygen sensor 209. In some examples, the controller 210 is separate from the NO generator 200. The NO generator 200 may include more than one respiration sensor 208.

In some examples, the electrodes 206 can be duplicated for safety purposes to provide a spare. The electrodes 206 can be doubled or tripled for increased power and NO production, e.g., with large tidal volumes.

The electrodes, power feed, and sensor wires can be embedded in the wall of the tracheostomy or endotracheal tube 204. The electrodes may be positioned within the tube, or placed in a small enclosure or well in the wall of the tube. The enclosure can be a spark reaction chamber that is covered by a microporous membrane to shield the electrodes from mucus or respiratory secretions. The membrane can also be a semipermeable membrane (permselective) such as DMPS that passes NO without passing water vapor. The membrane can be any membrane for passing NO without passing NO₂. A small internal scraper can be placed over the membrane to remove adherent mucus or respiratory secretions that might prevent diffusion of the NO into the lumen. The scraper may be controlled externally.

The controller 210 may be internal to or external from the user. For example, the controller 210 may be coupled to a user (e.g., an arm band or belt) or implanted subcutaneously in the user. Electrodes 206, respiration sensor 208, and leads 212 may be embedded in the wall of tracheostomy or endotracheal tube 204 or positioned inside or affixed to an exterior of the tracheostomy or endotracheal tube 204. Leads 212 may be insulated with an inert material. The leads 212 can be coupled to the electrodes 206 and the respiration sensor 208. In some examples, the leads 212 can be separately placed via a needle puncture between the cartilaginous tracheal rings (Seldinger technique). Respiration sensor 208 may be, for example, one or more of a pressure sensor, a temperature sensor, a gas velocity sensor (e.g., a heated wire anemometer), a tidal volume sensor, an abdominal or thoracic plethysmographic band (Respitrace™) or the like. In some cases, electrodes 206 and/or respiration sensor 208 are at least partially covered by a shield 214. Shield 214 may be positioned proximate to a balloon 216 of the tracheostomy or endotracheal tube 204, designed to insulate the airway from electrical shock and to keep electrodes 206 and respiration sensor 208 clean.

In some cases, a sweeping device, brush, scraper, sander or other cleaning device, automated or not, is coupled to shield 214. Shield 214 may also include a filter, e.g., a microporous membrane such as polytetrafluoroethylene, or a diffusible but permselective membrane such as PDMB, or polymethylpentene (PMP), so that by-products generated at electrodes 206 (such as NO₂ and O₃) do not pass into the airway. The filter or membrane may also keep particulate matter or vapor in the airway such as humidity and mucus from contacting the electrodes 206 and respiration sensor 208.

FIG. 2B shows an example of an alternative arrangement for the NO generator 200 coupled to the tracheostomy or endotracheal tube 204. In this example, the shield 214 includes a permselective membrane 218. The area where the electrodes 206 reside (e.g., inside the NO generator 200) is referred to as a spark chamber. The permselective membrane 218 can be approximately 10-50 microns thick, and may be affixed to a support mesh. The permselective membrane 218 can allow NO to pass from the NO generator 200 (e.g., the spark chamber) to the airway while preventing NO₂ and O₃ from passing from the NO generator 200 (e.g., the spark chamber) to the airway. The permselective membrane 218 can also prevent water vapor from passing from the airway to the NO generator 200. In some examples, the permselective membrane 218 can be a microporous membrane. In this example, the respiration sensor 208 resides in the tracheostomy or endotracheal tube 204. However, the respiration sensor 208 can also reside in the NO generator 200, as described with reference to FIG. 2A. In some examples, a sweeping device is coupled to the NO generator 200. The sweeping device is configured to remove mucus from the permselective membrane 218. The sweeping device may be automated.

FIG. 2C shows an example of an NO generator 220 for producing NO that is attached to a mask 222 that can be worn by a patient. Portions of the NO generator 220 can be placed within a nasal cavity, for example in the vestibule behind the naris, as in the NO generator 200 of FIG. 2A. The mask 222 can be part of a respiratory system. The mask 222 is configured to be positioned over a user's face, with electrodes 228 and respiration sensor 230 coupled to the mask 222 and positioned proximate the nasal opening of a user. In some examples, the NO generator 220 includes an oxygen sensor 234. The NO generator 220 may reside in an inspiratory line 240 that feeds into the mask 222. The mask 222 can include one or more valves (e.g., inspiratory valve 236 and expiratory valve 238) for separating inspiratory gas flow from the inspiratory line 240 from expiratory gas flow through the expiratory line 242. A controller 232 may be coupled to the NO generator 220. The controller 232 may be coupled to mask 222 or to the user. In some examples, the electrodes 228 and respiration sensor 230 can be positioned in a nostril of the user. The NO generator 220 functions as described above with respect to the NO generator 200 of FIG. 2A. The entry to the mask 222 may have one or more valves, an inspiration line, and an expiration line. The NO generator 220 may be placed in the inspiration line.

FIG. 2D shows an example of an NO generator 250 for producing NO that can reside within a trachea 252. In some examples, the NO generator 250 is small enough to be implanted using the Seldinger technique. The NO generator 250 includes electrodes 254 and a respiration sensor 256 (e.g., including a thermistor). The NO generator 250 may be covered by a shield 258 to insulate the airway from electrical shock and to keep the electrodes 254 and respiration sensor 256 clean. The NO generator may also include a membrane 260. The membrane 260 may be a permselective membrane that can allow NO to pass from the NO generator 250 to the airway while preventing NO₂ and O₃ from passing from the NO generator 250 to the airway. The membrane 260 can also prevent water vapor from passing from the airway to the NO generator 250. Wires 262 can connect a power source 264 to the NO generator 250. The wires 262 can be insulated to protect tissue from electric shock. A controller (e.g., controller 266) may be configured to communicate with the NO generator 266. The controller 266 may be configured to wirelessly communicate with the NO generator 250. In some examples, the NO generator 250 includes the controller 266, and the controller 266 resides within the trachea 252.

Referring back to FIG. 2A, the NO generator 200 operates as described herein to generate NO in the airway of a mammal based on a triggering event (e.g., volume and timing of gas flow, change in inspired gas temperature, or change in pressure), as detected by respiration sensor 208 in some examples. The controller 210, operatively coupled to respiration sensor 208, coordinates triggering of a voltage source in the controller 210 to deliver a series of electrical pulses to electrodes 206, thereby generating NO in the airway of the mammal during inspiration. The controller 210 can determine one or more control parameters based on information that is collected from the respiration sensor 208 (e.g., information related to one or more triggering events). The controller 210 may be configured to initiate a series of sparks and to control parameters such as spark duration, spark frequency, and the like to generate the needed amount of NO and minimal amount of NO₂. In some examples, the voltage source in the controller 210 can be a primary cell battery, a rechargeable battery, or a piezoelectric generator.

The controller 210 can determine one or more control parameters based on information received from an oxygen sensor (e.g., oxygen sensor 112 of FIG. 1). For example, the determined control parameters can be based on the concentration of oxygen in the reactant gas.

In some examples, the respiration sensor 208 is configured to measure the tidal volume of inspired gas. The controller 210 can determine one or more control parameters based on the inspired gas volume measurements. For example, the control parameters can be based on an actual or expected volume of an inspiration.

Adult humans normally breathe from 10-20 times per minute, each breath having a duration of 3-6 seconds. Typically, about one half to one third of the breath duration is inspiration. On average, each breath has a tidal volume of about 500 ml. In children, each breath typically has less volume, but breathing occurs at a higher rate.

The expected volume of an inspiration can be calculated using previous tidal volume measurements. For example, the controller 210 may determine that the expected tidal volume of a subsequent inspiration is going to be the same as the tidal volume measurement for the most recent inspiration. The controller 210 can also average the tidal volumes of several prior inspirations to determine the expected tidal volume of a subsequent inspiration. In some instances, mechanical ventilation is applied via a mask to support ventilation. In those cases, the inspiratory volume and timing of inspiration can be fed to the controller from the ventilator device.

FIG. 3 shows a representation of a pulse train 300 that is triggered by the controller 210. The controller 210 can determine one or more control parameters to create a pulse train. FIG. 3 also shows zoomed in view of one of the pulse groups 302 of the pulse train 302. Electrical pulses are delivered to the electrodes 206, and the electrodes 206 generate a series of sparks (sometimes referred to as electric arcs). The timing of the pulses (and of the resulting sparks) is controlled by the controller 210, and can be optimized to produce the needed amount of NO while producing minimal NO₂ and O₃. Multiple sparks make up a pulse group, and multiple pulse groups make up the pulse train. Thus, the pulse train 302 initiates the series of electric arcs.

Variables B and N control the overall energy that is created by the electrodes 206. Variable N sets the number of sparks per pulse group, and variable B sets the number of pulse groups per second. The values for B and N influence the amount of NO, NO₂, and O₃ that is created. The values for B and N also influence how much heat is produced by the electrodes 206. Larger values of either B or N create more NO and cause the electrodes 206 to produce more heat.

Variables E, F, H, and P control the timing of the sparks produced in each pulse group. Variable H is the high time of a pulse (e.g., the amount of time the voltage source of the controller 210 is activated for each electrical pulse). The high time is sometimes referred to as the pulse width. P is the amount of time between pulses. Thus, P minus H represents a period of time when no pulses occur (e.g., the voltage source of the controller 210 is not active). Larger values of H and smaller values of P result in the electrodes 206 producing more energy. When the electrodes 206 create a spark, plasma is established. The temperature of the plasma is proportional to the amount of energy produced by the electrodes 206.

The chemical reactions that cause NO and NO₂ to be produced are a function of plasma temperature. That is, higher plasma temperatures result in more NO and NO₂ being produced. However, the relative proportions of the produced NO and NO₂ vary across different plasma temperatures. In some examples, the sparks generated by the first two pulses in a pulse group establish the plasma. The first two sparks can have a high time that is longer than the sparks produced by the rest of the pulses in the pulse group. The amount of time that the first two pulses are extended is represented by variables E and F, respectively. Sparks generated by pulses beyond the first two pulses require less energy to maintain the plasma, so the high time of subsequent pulses (represented by variable H) can be shorter to prevent the plasma temperature from getting too high. For instance, while a relatively high plasma temperature may result in more NO, NO₂, and O₃ being produced, the relatively high plasma temperature may not be ideal for producing the desired proportions of NO and NO₂.

Many factors can affect the amount and proportions of NO, NO₂, and O₃ that is produced. For example, the material of the electrodes 206 plays a major role in determining how much energy is needed to generate a particular spark. Electrodes that include a noble metal may produce a low ratio of NO₂/NO. In some examples, tungsten electrodes produce a relatively high ratio of NO₂/NO, nickel electrodes produced a lower ratio of NO/NO, and iridium electrodes produce an even lower ratio of NO₂/NO, as shown in FIG. 8.

Each spark that is generated creates a particular amount of NO. The NO is diluted in the volume of gas that is inspired. To ensure the concentration of NO in the inspired gas is at an expected and sufficient level to produce the desired physiological effect, the controller 210 receives information related to the tidal volume of inspired gas from the respiration sensor 208 to determine control parameters for maintaining an appropriate NO concentration.

Implementations of the controller 210 can include digital electronic circuitry, or computer software, firmware, or hardware, including the structures disclosed in this specification and their structural equivalents, or combinations of one or more of them. For example, the controller 210 can be a microprocessor based controller (or control system) as well as an electro-mechanical based controller (or control system). Instructions and/or logic in the controller 210 can be implemented as one or more computer programs, i.e., one or more modules of computer program instructions, encoded on computer storage medium for execution by, or to control the operation of, data processing apparatus. Alternatively or in addition, the program instructions can be encoded on an artificially generated propagated non-transitory signal, e.g., a machine-generated electrical, optical, or electromagnetic signal that is generated to encode information for transmission to suitable receiver apparatus for execution by a data processing apparatus.

The controller 210 can include clients and servers and/or master and slave controllers. A client and server are generally remote from each other and typically interact through a communication network. The relationship of client and server arises by virtue of computer programs running on the respective computers and having a client-server relationship to each other. In some aspects, the controller 210 represents a main controller (e.g., master) communicably coupled through communication elements (e.g., wired or wireless) with each of the components of the NO generator 200.

The controller 210 may be configured to communicate with the NO generator 200 wirelessly (e.g., via Bluetooth). The controller 210 can also be configured to communicate with external devices (e.g., a computer, tablet, smart phone, or the like). The external devices can then be used to perform functions of the controller 210 or to aid the controller 210 in performing functions.

In some examples, the controller 210 can disable certain components of the NO generator 200 during, before or after a series of sparks is generated. In some examples, the controller 210 can also include features to: i) detect and cease unintended sparks; ii) confirm that a series of sparks is safe before triggering the series of sparks; iii) verity that timing values are checked against back-up copies of timing values after every series of sparks is generated to detect timing variable corruption; and iv) determine whether back-up copies of timing variables are corrupt.

In some examples, the NO generator 200 can be positioned or included with nasal tubes, endotracheal tubes, and the like. Electrodes 206 and respiration sensor 208 may be cleanable or replaceable. In some examples, the electrodes 106 and sensor 208 may be removed from the tracheostomy or endotracheal tube 204 and cleaned or replaced.

Sparking upon inspiration in the NO generator 200 tags the front of the inspired gas bolus with electrically synthesized fresh NO. In some examples, it is desirable to generate NO only at the start of inspiration. This minimizes the amount of freshly produced NO produced, reduces environmental pollution, and effectively delivers the NO most rapidly without dilution into terminal bronchi and alveolar gas where it can actively dilate the pulmonary blood vessels (the alveoli and distal airways). After a brief period of time. NO begins to oxidize into NO₂ which, when dissolved in water, forms nitric acid and nitrate salts. If NO is produced long before a user is ready to inhale it, the NO can be oxidized by the time of inspiration. The nitric acid and nitrate salts can cause damage to the components of the NO generator 200 as well as to the airways and lung tissue.

In some examples, to augment the dose, it may be desirable to generate NO at the end of exhalation and slightly prior to the start of an inspiration. This is sometimes referred to as pre-triggering. The controller 210 can initiate the series of electric arcs for a pre-defined amount of time before the triggering event occurs. Such pre-triggering may be necessary when there is a large volume of inspired gas or when a high concentration of inhaled NO is desired. The controller 210 can track the inspiratory timing and volume of inspired gas and use prior timings to predict the timing of a subsequent inspiration. The tracked information can be used to calculate a pre-defined amount of time that represents an estimate of when the next inspiration will occur. In some examples, the controller 210 can initiate the series of electric arcs approximately when the triggering event occurs (e.g., slightly before or slightly after the triggering event). Pre-triggering can be optimized to ultimately deliver greater NO concentrations in the inspired gas.

The spark can be triggered at the onset of inspiration in a number of ways. In some examples, the respiration sensor 208 detects an inspiration. The respiration sensor 208 can include a high speed response thermistor that is located near the electrodes 206 in the airway. The respiration sensor 208 can sense a change in temperature (inspired air is often slightly cooler than expired air). Thus the cool inspiratory gas can trigger a series of sparks. That is, an inspiration, or part of an inspiration, can be a triggering event. More specifically, a reduction of temperature due to an inspiration of air can be a triggering event.

Different types of circuitry can be incorporated into the NO generator 200 and its components. FIG. 4 shows a circuit diagram 400 of an example of a portion of a respiration sensor 208 that can be used to detect an inspiration. The respiration sensor 208 can monitor the temperature of the air in the airway. The respiration sensor can include a thermistor 402. The resistance of the thermistor 402 increases when it is cooled and decreases when it is warmed.

In this example, the respiration sensor 208 is set up as a voltage divider that includes the thermistor 402 and another resistor. An alternative configuration is to use a thermistor in a bridge configuration with other resistors. During inspiration, room or inspired temperature gas is inhaled past the thermistor 402. During expiration, gas that is typically warmer than room temperature (e.g., gas that is at or near body temperature) passes the thermistor 402. That is, during typical operation, the thermistor 402 increases in resistance during inspiration and decreases in resistance during expiration. The change in resistance of the thermistor 402 results in a varying voltage in the middle node of the voltage divider. This varying voltage may be modified by one or more amplifiers.

The respiration sensor 208 can include a differentiator that outputs a voltage that is proportional to the varying voltage of the voltage divider. This voltage can be sent to the controller 210 and converted into a digital voltage value. The controller 210 can use the digital voltage value to determine the start of an inspiration. Alternatively, the output of the differentiator can be modified by an amplifier and then fed into a Schmitt trigger. The Schmitt trigger can convert the voltage into a digital voltage value and create a hysteresis. The hysteresis can help differentiate between small temperature decreases seen late in an expiration period (which are to be ignored), and larger temperature decreases seen at the start of an inspiration period (which are of interest). The digital voltage value can be sent to the controller 210, which can recognize the start of an inspiration.

FIG. 5 shows an example of a voltage time series 500 of a respiration sensor 208. As explained above, during inspiration, relatively cool inhaled gas passes the thermistor 402. The cool inspired gas causes the resistance of the thermistor to increases, which in turn causes the voltage at the middle node of the voltage divider to increase, as reflected in region 502. During expiration, relatively warm gas near core body temperature (approximately 37 degrees Celsius) passes by the thermistor 402. The warm gas causes the resistance of the thermistor to decrease, which in turn causes the voltage at the middle node of the voltage divider to decrease, as reflected in region 504.

In some examples, the respiration sensor 208 can be a tube contiguous with the area near the electrodes 206 that can sense pressure. Spontaneous inspiration is triggered by a lower airway and intrathoracic pressure, whilst mechanical ventilation produces a positive airway pressure (to inflate the lungs). Thus, pressure sensing of inspiration, whether positive (mechanical ventilation) or negative (spontaneous inspiration) could trigger the spark. In some examples, a hot wire anemometer or a pneumotachograph can sense respiratory timings and volume.

In some examples, a circumferential chest belt containing a resistor (e.g., mercury strain gauge) or impedance sensor could sense the expansion of the chest (or abdomen) and thereby trigger the spark to produce NO upon the onset of inspiration. In certain cases, if the patient is on a respirator, the mechanical respirator or ventilator can trigger the endotracheal or tracheostomy pulse of synthesizing electricity (because the ventilator can know the timing, tidal volume of the inspiration, and the inspired oxygen concentration) to produce the necessary amount of NO by sparks timed to the onset of ventilator inspiration.

In cases where the respiration sensor 208 does not measure temperature, the respiration sensor 208 can be configured to detect when an inspiration or expiration occurs. The respiration sensor 208 can also differentiate between an inspiration and an expiration. For example, the respiration sensor 208 can detect the air flow direction of air passing by the respiration sensor 208 to determine whether the air is being inspired or expired.

Results achieved with the NO generator 200 (and the NO generator mask 220 of FIG. 2B) are described herein.

FIG. 6A is an average current and voltage chart 600 that shows the average current and voltage vs. sparks/second for NO generator 200. FIG. 6B is an average power chart 602 that shows the average power vs. sparks/second for NO generator 200. Average current and power peak between 0.5 and 2 sparks/second, and average voltage dips over the same range. FIG. 7A shows oscilloscope traces 700 for voltage (upper trace) and current (lower trace) during 2 sparks of a 1 spark/second discharge. FIG. 7B shows oscilloscope traces 702 for voltage (upper trace) and current (lower trace) traces for a 1 spark/second discharge with a spark duration (single spark) of 27 msec.

Animal Study 1

Four lambs weighing approximately 32 kg were studied. General anesthesia was induced with 5% inhaled isoflurane (1-chloro-2,2,2-trifluoroethyldifluromethyl ether, Baxter, Deerfield, Ill.) in oxygen via a mask and then maintained with 1-4% isoflurane at an initial inspired oxygen fraction (FiO₂) of 0.40. After tracheal intubation, animals were instrumented with indwelling carotid artery and pulmonary artery Swan-Ganz catheters. All hemodynamic measurements were performed in the anesthetized lambs. All lambs were ventilated with a mechanical ventilator (model 7200, Puritan Bennett, Pleasanton, Calif.) at tidal volume 400 ml and rate 12 breaths/min.

To induce pulmonary hypertension, the potent pulmonary vasoconstrictor U46619 (Cayman Chemical, Ann Arbor, Mich.), the analog of the endoperoxide prostaglandin H₂, was infused intravenously at a rate of 0.8-0.9 μg/kg/min to increase the mean pulmonary artery pressure (PAP) to 30 mmHg.

To study the pulmonary vasodilator effect of nitric oxide (NO) produced by electric discharge, either a mini spark plug or iridium spark plug was placed in the inspiratory line of the sheep ventilator while airway gas flow measurements were measured by software (NICO Respironics, Wallingford, Conn.) to determine inspiration, expiration, and the tidal volume of each mechanical breath. Electrodes of the spark plug generated a series of sparks as described with reference to FIG. 3. In some studies, sparks were produced continuously throughout the respiratory cycle (continuous sparking). In other studies, sparks were produced on each breath commencing with inspiration, or shortly before inspiration began (intermittent sparking for 0.8 seconds/breath, 12-15 breaths/min). This was done to avoid wasted NO production during the expiratory phase of respiration.

FIG. 8 shows NO and NO₂ concentrations from an NO generator (e.g., NO generator 102 of FIG. 1) using various electrode materials. The test conditions included the use of a ¼″ rod, an electrode gap of 2.0 mm, constant air flow at 5 L/min, and an FiO₂ of 0.21. For the tungsten electrode, B=40 pulse groups per second, N=30 sparks per pulse group, P=100 microseconds, and H=20 microseconds. For the nickel electrodes, B=35 pulse groups per second, N=40 sparks per pulse group, H=180 microseconds, and P=70 microseconds. For the iridium electrodes, B=35 pulse groups per second, N=40 sparks per pulse group, H=180 microseconds, and P=80 microseconds.

FIG. 9 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations from the NO generator using mini spark plug (Micro Viper Z3 with 6 mm HEX and 10-40 THRD, Rimfire, Benton City, Wash.) with continuous sparking.

FIG. 10 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations from the NO generator using an iridium spark plug (ACDelco 41-101, Waltham, Mass.) with continuous sparking.

FIG. 11 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations from the NO generator using iridium spark plug with intermittent sparking.

Ozone (O₃) is a powerful oxidant that has many industrial and consumer applications related to oxidation. However, its oxidizing potential is high, and it is a toxic gas causing damage to mucus membranes and respiratory tissues in animals, and also to tissues in plants. This makes ozone a potent respiratory hazard and pollutant near ground level. Ozone is formed from atmospheric electrical discharges, and reacts with NO to form nitric dioxide (NO₂) and O₂ or reacts with N₂ to produce NO and O₂. In some examples, ozone levels are greater with continuous sparking than with intermittent sparking, and also increase with increasing O₂ concentrations.

FIG. 12 shows O₃ levels at various O₂ concentrations using the mini spark plug and iridium spark plug with continuous sparking. In this example, B=60 pulse groups per second, N=50 sparks per pulse group, P=140 microseconds, H=40 microseconds, and air flow rate is 5 L/min.

FIG. 13 shows O₃ levels at various O₂ concentrations using the mini spark plug and iridium spark plug with intermittent sparking triggered on each breath commencing with inspiration, or shortly before inspiration began. In this example, B=60 pulse groups per second, N=50 sparks per pulse group, P=140 microseconds, H=40 microseconds, and air flow rate is 5 L/min.

FIG. 14 shows O₃ levels at various O₂ concentrations using the mini spark plug and iridium spark plug with continuous sparking. In this example, B=35 pulse groups per second, N=25 sparks per pulse group, P=240 microseconds, H=100 microseconds, and air flow rate is 5 L/min.

FIG. 15 shows O₃ levels at various O₂ concentrations using the mini spark plug and iridium spark plug with intermittent sparking triggered on each breath commencing with inspiration, or shortly before inspiration began. In this example, B=35 pulse groups per second, N=25 sparks per pulse group, P=240 microseconds, H=100 microseconds, and air flow rate is 5 L/min.

FIG. 16 shows NO and NO₂ concentrations at various reactant gas oxygen concentrations using an oxygen concentrator. In this example, B=5 pulse groups per second, N=25 sparks per pulse group, P=200 microseconds, H=60 microseconds, and air flow rate is 5 L/min.

FIG. 17 shows mean pulmonary artery pressure (PAP) during infusion of U46619. At baseline, before U46619 infusion was begun, the PAP was 14 mmHg. Over 30 minutes of infusion, the mean PAP increased to 28 mmHg. After PAP was stable, sparks were generated at the beginning of each inspiration for a period of four minutes. Over the four minute period, the PAP was significantly decreased to 22 mmHg. After ceasing sparking and waiting a four minute period, mean PAP again rose to 28 mmHg. In this example, B=60 pulse groups per second, N=100 sparks per pulse group, P=140 microseconds, H=17 microseconds, and tidal volume (Vt)=400 ml.

FIG. 18 shows NO and NO₂ concentrations at various FiO₂ while producing intermittent sparks triggered by inspiratory flow using an iridium spark plug.

FIG. 19 shows mean PAP at various FiO₂ levels during U46619 infusion before and after producing intermittent sparks. In these examples, B=35 pulse groups per second, N=25 sparks per pulse group, P=240 microseconds, H=100 microseconds, and Vt=400 ml.

FIG. 20 shows NO and NO₂ concentrations at various FiO₂ levels while producing continuous sparks triggered upon inspiratory flow using an iridium spark plug. FIG. 21 shows PAP at various FiO₂ levels during infusion of U46619 before and after producing continuous sparks. In these examples, B=35 pulse groups per second, N=25 sparks per pulse group, P=−240 microseconds, H=100 microseconds, and Vt=400 ml.

In some further examples, smaller breath sizes produce higher levels of NO because of reduced dilution of spark synthesized NO. FIG. 22 shows mean PAP at various Vt (respiratory tidal volume levels) during infusion of U46619 before and after producing NO with sparks triggered by inspiratory flow using an iridium spark plug. FIG. 23 shows NO and NO₂ concentrations in lambs at the various levels of tidal volume ventilation (Vt). In these examples, B=35 pulse groups per second, N=25 sparks per pulse group, P=−240 microseconds, H=100 microseconds, and FiO₂=0.21.

FIG. 24 shows a test setup for measuring NO and NO₂ levels in a hypobaric chamber 2400 at various atmospheric pressures. The results of the test are shown in FIG. 25. To create a negative pressure (e.g., ½ ATA, ⅓ ATA) inside the hypobaric chamber 2400, inlet and outlet valves were closed and a piston was translated away from the spark plug. The spark plug was then fired for 30 seconds. In this example, B=100 pulse groups per second, N=10 sparks per pulse group, P=140 microseconds, and H=10 microseconds. The piston was then translated toward the spark plug to bring the pressure in the hypobaric chamber 2400 back to 1 ATA. The outlet valve was opened, and gas samples were collected in a 3 L respiratory bag by further translating the piston toward the spark plug. The collected gas samples were analyzed with Sievers NOA i280 immediately after collection.

Animal Study 2

A mini spark plug (Micro Viper Z3 with 6 mm HEX and 10-40 THRD, Rimfire, Benton City, Wash.) was installed in the airway of sheep #1. The mini spark plug was triggered by a respiration sensor that measured the change in inspired gas temperature upon inspiration. Electrodes of the mini spark plug generated a series of sparks as described with reference to FIG. 3.

FIG. 26 shows PAP during an infusion of U46619 for a period of time. U46619 was IV infused at a concentration of 50 μg/ml at a rate of 18 ml/hour. At baseline, the mean PAP was 13 mmHg. Over 30 minutes of infusion, the mean PAP increased to 27-28 mmHg.

FIG. 27 shows mean PAP while the sheep is breathing NO at a concentration of 40 ppm from a tank. The mean PAP decreased to 18 mmHG after two minutes.

FIG. 28 shows mean PAP during sparking triggered by inspiratory breathing (e.g., triggered by the NICO a respiration sensor upon inspiration). In this example, B=1 pulse groups per second, N=70 sparks per pulse group, P=140 microseconds, and H=40 microseconds. In vitro at 200 ml/min, the NO concentration measured by chemiluminescence was 25 ppm.

FIG. 29 shows mean PAP during continuous sparking. In this example, B=1 pulse groups per second, N=407 sparks per pulse group, P=140 microseconds, and H=40 microseconds. In vitro at 200 ml/min, the NO concentration was 125 ppm.

A mini spark plug was installed in sheep #2's airway, as shown in FIG. 30. The mini spark plug was triggered by a respiration sensor that measured the change in inspired gas temperature upon inspiration. Electrodes of the mini spark plug generated a series of sparks as described with reference to FIG. 3.

FIG. 31 shows mean PAP during infusion of U46619 for a period of time. U46619 was infused at 50 μg/ml at 18 ml/hour. At baseline, the mean PAP was 12 mmHg. Over 30 minutes of infusion, the mean PAP increased to 27 mmHG.

FIG. 32 shows mean PAP while the sheep is breathing NO at a fixed concentration of 40 ppm delivered from a cylinder. The mean PAP decreased to 15 mmHg after two minutes.

FIG. 33 shows mean PAP during sparking triggered by inspiratory breathing (e.g., triggered by a NICO respiration sensor upon inspiration) with flow control. In this example, B=60 pulse groups per second, N=100 sparks per pulse group, P=140 microseconds, and H=17 microseconds.

Bench Test

FIG. 34 shows a bench test setup using a micro spark plug triggered by inspiration (flow controlled, NICO monitor) with a sheep airway simulator.

FIG. 35 shows NO production under a constant reactant gas flow rate of 1 L/min using a modified mini spark plug with a circuit gap (as shown in FIG. 36) under various conditions. In this example, H was increased from 10 to 17. Continuous sparking in air produced major amounts of NO (i.e., approximately 250 ppm). The tang electrode of the mini spark plug was removed during modification to increase the electrode gap from 0.4 mm to 1.1 mm.

Referring to FIG. 37, a flowchart 3700 represents an arrangement of operations of the controller (e.g., controller 210, shown in FIG. 2A). Typically, the operations are executed by a processor present in the controller. However, the operations may also be executed by multiple processors present in the controller. While typically executed by a single controller, in some arrangements, operation execution may be distributed among two or more controllers.

Operations include collecting 3702 information related to one or more triggering events associated with a respiratory system. For example, the respiration sensor 208 of FIG. 2A can collect information related one or more triggering events associated with a respiratory system. The information can include the onset time of an inspiration and the tidal volume of an inspiration (e.g., obtained from a NICO device, a hotwire anemometer, a pneumotachograph, etc.). The triggering event may be an inspiration. Operations also include determining 3704 one or more control parameter based on the collected information. For example, the controller 210 of FIG. 2A can determine one or more control parameters. The control parameters may create a pulse train. Operations also include initiating 3706 a series of electric arcs to generate nitric oxide based on the determined control parameters. For example, the electrodes 206 of FIG. 2A can initiate a series of electric arcs to generate nitric oxide based on the determined control parameters. The control parameters may control the timings of the series of electric arcs.

FIG. 38 shows an example of example computer device 3800 and example mobile computer device 3850, which can be used to implement the operations and techniques described herein. For example, a portion or all of the operations of the controller 110 (shown in FIG. 1), the controller 210 (shown in FIG. 2A), the controller 232 (shown in FIG. 2C), or the controller 266 (shown in FIG. 2D) may be executed by the computer device 3800 and/or the mobile computer device 3850. Computing device 3800 is intended to represent various forms of digital computers, including, e.g., laptops, desktops, workstations, personal digital assistants, servers, blade servers, mainframes, and other appropriate computers. Computing device 3850 is intended to represent various forms of mobile devices, including, e.g., personal digital assistants, tablet computing devices, cellular telephones, smartphones, and other similar computing devices. The components shown here, their connections and relationships, and their functions, are meant to be examples only, and are not meant to limit implementations of the techniques described and/or claimed in this document.

Computing device 3800 includes processor 3802, memory 3804, storage device 3806, high-speed interface 3808 connecting to memory 3804 and high-speed expansion ports 3810, and low speed interface 3812 connecting to low speed bus 3814 and storage device 3806. Each of components 3802, 3804, 3806, 3808, 3810, and 3812, are interconnected using various busses, and can be mounted on a common motherboard or in other manners as appropriate. Processor 3802 can process instructions for execution within computing device 3800, including instructions stored in memory 3804 or on storage device 3806 to display graphical data for a GUI on an external input/output device, including, e.g., display 3816 coupled to high speed interface 3808. In other implementations, multiple processors and/or multiple buses can be used, as appropriate, along with multiple memories and types of memory. Also, multiple computing devices 3800 can be connected, with each device providing portions of the necessary operations (e.g., as a server bank, a group of blade servers, or a multi-processor system).

Memory 3804 stores data within computing device 3800. In one implementation, memory 3804 is a volatile memory unit or units. In another implementation, memory 3804 is a non-volatile memory unit or units. Memory 3804 also can be another form of computer-readable medium, including, e.g., a magnetic or optical disk.

Storage device 3806 is capable of providing mass storage for computing device 3800. In one implementation, storage device 3806 can be or contain a computer-readable medium, including, e.g., a floppy disk device, a hard disk device, an optical disk device, or a tape device, a flash memory or other similar solid state memory device, or an array of devices, including devices in a storage area network or other configurations. A computer program product can be tangibly embodied in a data carrier. The computer program product also can contain instructions that, when executed, perform one or more methods, including, e.g., those described above. The data carrier is a computer- or machine-readable medium, including, e.g., memory 3804, storage device 3806, memory on processor 3802, and the like.

High-speed controller 3808 manages bandwidth-intensive operations for computing device 3800, while low speed controller 3812 manages lower bandwidth-intensive operations. Such allocation of functions is an example only. In one implementation, high-speed controller 3808 is coupled to memory 3804, display 3816 (e.g., through a graphics processor or accelerator), and to high-speed expansion ports 3810, which can accept various expansion cards (not shown). In the implementation, low-speed controller 3812 is coupled to storage device 3806 and low-speed expansion port 3814. The low-speed expansion port, which can include various communication ports (e.g., USB, Bluetooth®, Ethernet, wireless Ethernet), can be coupled to one or more input/output devices, including, e.g., a keyboard, a pointing device, a scanner, or a networking device including, e.g., a switch or router, e.g., through a network adapter.

Computing device 3800 can be implemented in a number of different forms, as shown in the figure. For example, it can be implemented as standard server 3820, or multiple times in a group of such servers. It also can be implemented as part of rack server system 3824. In addition or as an alternative, it can be implemented in a personal computer including, e.g., laptop computer 3822. In some examples, components from computing device 3800 can be combined with other components in a mobile device (not shown), including, e.g., device 3850. Each of such devices can contain one or more of computing device 3800, 3850, and an entire system can be made up of multiple computing devices 3800, 3850 communicating with each other.

Computing device 3850 includes processor 3852, memory 3864, an input/output device including, e.g., display 3854, communication interface 3866, and transceiver 3868, among other components. Device 3850 also can be provided with a storage device, including, e.g., a microdrive or other device, to provide additional storage. Each of components 3850, 3852, 3864, 3854, 3866, and 3868, are interconnected using various buses, and several of the components can be mounted on a common motherboard or in other manners as appropriate.

Processor 3852 can execute instructions within computing device 3850, including instructions stored in memory 3864. The processor can be implemented as a chipset of chips that include separate and multiple analog and digital processors. The processor can provide, for example, for coordination of the other components of device 3850, including, e.g., control of user interfaces, applications run by device 3850, and wireless communication by device 3850.

Processor 3852 can communicate with a user through control interface 3858 and display interface 3856 coupled to display 3854. Display 3854 can be, for example, a TFT LCD (Thin-Film-Transistor Liquid Crystal Display) or an OLED (Organic Light Emitting Diode) display, or other appropriate display technology. Display interface 3856 can comprise appropriate circuitry for driving display 3854 to present graphical and other data to a user. Control interface 3858 can receive commands from a user and convert them for submission to processor 3852. In addition, external interface 3862 can communicate with processor 3842, so as to enable near area communication of device 3850 with other devices. External interface 3862 can provide, for example, for wired communication in some implementations, or for wireless communication in other implementations, and multiple interfaces also can be used.

Memory 3864 stores data within computing device 3850. Memory 3864 can be implemented as one or more of a computer-readable medium or media, a volatile memory unit or units, or a non-volatile memory unit or units. Expansion memory 3874 also can be provided and connected to device 3850 through expansion interface 3872, which can include, for example, a SIMM (Single In Line Memory Module) card interface. Such expansion memory 3874 can provide extra storage space for device 3850, or also can store applications or other data for device 3850. Specifically, expansion memory 3874 can include instructions to carry out or supplement the processes described above, and can include secure data also. Thus, for example, expansion memory 3874 can be provided as a security module for device 3850, and can be programmed with instructions that permit secure use of device 3850. In addition, secure applications can be provided through the SIMM cards, along with additional data, including, e.g., placing identifying data on the SIMM card in a secure, non-modifiable manner.

The memory can include, for example, flash memory and/or NVRAM memory, as discussed below. In one implementation, a computer program product is tangibly embodied in a data carrier. The computer program product contains instructions that, when executed, perform one or more methods, including, e.g., those described above. The data carrier is a computer- or machine-readable medium, including, e.g., memory 3864, expansion memory 3874, and/or memory on processor 3852, which can be received, for example, over transceiver 3868 or external interface 3862.

Device 3850 can communicate wirelessly through communication interface 3866, which can include digital signal processing circuitry where necessary. Communication interface 3866 can provide for communications under various modes or protocols, including, e.g., GSM voice calls, SMS, EMS, or MMS messaging, CDMA, TDMA, PDC, WCDMA, CDMA2000, or GPRS, among others. Such communication can occur, for example, through radio-frequency transceiver 3868. In addition, short-range communication can occur, including, e.g., using a Bluetooth®, WiFi, or other such transceiver (not shown). In addition, GPS (Global Positioning System) receiver module 3870 can provide additional navigation- and location-related wireless data to device 3850, which can be used as appropriate by applications running on device 3850. Sensors and modules such as cameras, microphones, compasses, accelerators (for orientation sensing), etc. maybe included in the device.

Device 3850 also can communicate audibly using audio codec 3860, which can receive spoken data from a user and convert it to usable digital data. Audio codec 3860 can likewise generate audible sound for a user, including, e.g., through a speaker, e.g., in a handset of device 3850. Such sound can include sound from voice telephone calls, can include recorded sound (e.g., voice messages, music files, and the like) and also can include sound generated by applications operating on device 3850.

Computing device 3850 can be implemented in a number of different forms, as shown in the figure. For example, it can be implemented as cellular telephone 3880. It also can be implemented as part of smartphone 3882, personal digital assistant, or other similar mobile device.

Various implementations of the systems and techniques described here can be realized in digital electronic circuitry, integrated circuitry, specially designed ASICs (application specific integrated circuits), computer hardware, firmware, software, and/or combinations thereof. These various implementations can include implementation in one or more computer programs that are executable and/or interpretable on a programmable system including at least one programmable processor, which can be special or general purpose, coupled to receive data and instructions from, and to transmit data and instructions to, a storage system, at least one input device, and at least one output device.

These computer programs (also known as programs, software, software applications or code) include machine instructions for a programmable processor, and can be implemented in a high-level procedural and/or object-oriented programming language, and/or in assembly/machine language. As used herein, the terms machine-readable medium and computer-readable medium refer to a computer program product, apparatus and/or device (e.g., magnetic discs, optical disks, memory, Programmable Logic Devices (PLDs)) used to provide machine instructions and/or data to a programmable processor, including a machine-readable medium that receives machine instructions.

To provide for interaction with a user, the systems and techniques described here can be implemented on a computer having a display device (e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor) for displaying data to the user and a keyboard and a pointing device (e.g., a mouse or a trackball) by which the user can provide input to the computer. Other kinds of devices can be used to provide for interaction with a user as well; for example, feedback provided to the user can be a form of sensory feedback (e.g., visual feedback, auditory feedback, or tactile feedback); and input from the user can be received in a form, including acoustic, speech, or tactile input.

The systems and techniques described here can be implemented in a computing system that includes a back end component (e.g., as a data server), or that includes a middleware component (e.g., an application server), or that includes a front end component (e.g., a client computer having a user interface or a Web browser through which a user can interact with an implementation of the systems and techniques described here), or a combination of such back end, middleware, or front end components. The components of the system can be interconnected by a form or medium of digital data communication (e.g., a communication network). Examples of communication networks include a local area network (LAN), a wide area network (WAN), and the Internet.

The computing system can include clients and servers. A client and server are generally remote from each other and typically interact through a communication network. The relationship of client and server arises by virtue of computer programs running on the respective computers and having a client-server relationship to each other.

In some implementations, the engines described herein can be separated, combined or incorporated into a single or combined engine. The engines depicted in the figures are not intended to limit the systems described here to the software architectures shown in the figures. 

What is claimed is:
 1. An apparatus comprising: a reaction chamber including one or more pairs of electrodes configured to generate a series of electric arcs to synthesize a reactant gas containing at least nitrogen and oxygen to a product gas containing nitric oxide, the reaction chamber being at least partially positioned within a tube into which the product gas is delivered; a sensor configured to measure one or more characteristics of a flow of a gas in the tube; an oxygen sensor being configured to measure a concentration of oxygen in the reactant gas; and a controller in communication with the one or more pairs of electrodes, the oxygen sensor, and the sensor, the controller being configured to initiate the series of electric arcs based on the one or more characteristics of the flow of the gas in the tube and the concentration of oxygen in the reactant gas to minimize a concentration of NO2 in the product gas.
 2. The apparatus of claim 1, wherein the one or more pairs of electrodes include a noble metal.
 3. The apparatus of claim 1, wherein the one or more pairs of electrodes include iridium.
 4. The apparatus of claim 1, wherein the one or more characteristics include at least one of a direction of the flow of the gas, a tidal volume of the flow of the gas, a timing of the flow of the gas, a change in temperature of the flow of the gas, a change in pressure of the flow of the gas, and a flow rate of the gas.
 5. The apparatus of claim 1, wherein the controller is configured to adjust at least one of a pulse width, pulse period, pulse count per pulse group, pulse groups per second, and an arc frequency supplied to the one or more pairs of electrodes to control a concentration of nitric oxide in the product gas.
 6. The apparatus of claim 1, wherein the tube comprises one of a tracheostomy tube, an endotracheal tube, a nasal tube, a ventilator tube, and an inspiratory line.
 7. An apparatus comprising: a reaction chamber including one or more pairs of electrodes configured to generate a series of electric arcs to synthesize a reactant gas containing nitrogen and oxygen to a product gas containing nitric oxide, the reaction chamber being at least partially positioned within a tube into which the product gas is delivered; a sensor configured to measure one or more characteristics of a flow of a gas in the tube; an oxygen sensor being configured to measure a concentration of oxygen in the reactant gas; and a controller in communication with the one or more pairs of electrodes, the oxygen sensor, and the sensor, the controller being configured to adjust one or more control parameters within the reaction chamber based on the concentration of oxygen in the reactant gas to control a concentration of nitric oxide in the product gas.
 8. The apparatus of claim 7, wherein the one or more pairs of electrodes include a noble metal.
 9. The apparatus of claim 7, wherein the one or more pairs of electrodes include iridium.
 10. The apparatus of claim 7, wherein the one or more control parameters within the reaction chamber include at least one of a pulse width, pulse period, pulse count per pulse group, pulse groups per second, and an arc frequency supplied to the one or more pairs of electrodes.
 11. The apparatus of claim 7, wherein the one or more characteristics include at least one of a direction of the flow of the gas, a tidal volume of the flow of the gas, a timing of the flow of the gas, a change in temperature of the flow of the gas, a change in pressure of the flow of the gas, and a flow rate of the gas.
 12. The apparatus of claim 11, wherein controller is configured to trigger the series of electric arcs based on the one or more control parameters of the flow of the gas in the tube.
 13. The apparatus of claim 7, wherein the tube comprises one of a tracheostomy tube, an endotracheal tube, a nasal tube, a ventilator tube, and an inspiratory line.
 14. The apparatus of claim 7, wherein the controller adjusts the one or more control parameters within the reaction chamber to minimize a NO2/NO concentration ratio in the product gas.
 15. An apparatus comprising: a reaction chamber coupled to a respiratory system, wherein the respiratory system includes a tube in fluid communication with an airway, the reaction chamber being arranged at least partially within the tube; one or more pairs of electrodes within the reaction chamber and configured to generate a series of electric arcs to synthesize a reactant gas containing nitrogen and oxygen to a product gas containing nitric oxide, the one or more pairs of electrodes including a noble metal; an oxygen sensor being configured to measure a concentration of oxygen in the reactant gas; and a controller in communication with the one or more pairs of electrodes and the oxygen sensor, the controller being configured to adjust one or more control parameters within the reaction chamber based on the concentration of oxygen in the reactant gas to control a concentration of nitric oxide in the product gas, and minimize a concentration of NO2 in the product gas.
 16. The apparatus of claim 15, further comprising a sensor configured to measure one or more characteristics of a flow of a gas in the tube, the sensor in communication with the controller.
 17. The apparatus of claim 16, the one or more characteristics include at least one of a direction of the flow of the gas, a tidal volume of the flow of the gas, a timing of the flow of the gas, a change in temperature of the flow of the gas, a change in pressure of the flow of the gas, and a flow rate of the gas.
 18. The apparatus of claim 15, wherein the one or more control parameters within the reaction chamber include at least one of a pulse width, pulse period, pulse count per pulse group, pulse groups per second, and an arc frequency supplied to the one or more pairs of electrodes.
 19. The apparatus of claim 15, wherein the one or more pairs of electrodes include iridium.
 20. A method for generating nitric oxide, the method comprising: measuring one or more characteristics of at least one of a flow of a gas in a tube of a respiratory system and a flow of gas into a reaction chamber, the tube being in fluid communication with an airway and including at least a portion of a reaction chamber therein; initiating a series of electric arcs in the reaction chamber based on the one or more characteristics to synthesize a reactant gas containing nitrogen and oxygen to a product gas containing nitric oxide, the one or more characteristics including an oxygen concentration in the reactant gas; and adjusting one or more control parameters within the reaction chamber based on the oxygen concentration in the reactant gas to control a concentration of nitric oxide in the product gas.
 21. The method of claim 20, wherein the one or more characteristics include at least one of a direction of the flow of the gas, a tidal volume of the flow of the gas, a timing of the flow of the gas, a change in temperature of the flow of the gas, a change in pressure of the flow of the gas, and a flow rate of the gas.
 22. The method of claim 20, wherein the one or more control parameters within the reaction chamber include at least one of a pulse width, pulse period, pulse count per pulse group, pulse groups per second, and an arc frequency supplied to one or more pairs of electrodes arranged within the reaction chamber. 